CN114571597B - Concrete placement equipment for hydraulic engineering construction - Google Patents

Abstract

The invention is applicable to the technical field of hydraulic engineering construction, and provides concrete pouring equipment for hydraulic engineering construction, which comprises: the tank body is arranged between the supporting frames, and a stirring mechanism is arranged in the tank body; the feeding pipe is arranged on the supporting frame, and a pouring pipe is arranged at one side of the tank body; and the control mechanism is arranged on the supporting frame and is connected with the stirring mechanism. When this concrete placement equipment for hydraulic engineering construction uses, add the concrete raw materials to jar internal portion through the inlet pipe, then start rabbling mechanism, then rabbling mechanism can stir the concrete raw materials, start control mechanism simultaneously, control mechanism can drive rabbling mechanism and carry out sustainable position adjustment, constantly change rabbling mechanism's working position, make jar internal portion hungry concrete's stirring more abundant, avoid edge portion to have stone residue to remain, promote the treatment effect of concrete.

Description

Concrete placement equipment for hydraulic engineering construction

Technical Field

The invention belongs to the technical field of hydraulic engineering construction, and particularly relates to concrete pouring equipment for hydraulic engineering construction.

Background

The hydraulic engineering construction has many similarities with the construction of general civil engineering such as roads, railways, bridges, house buildings and the like, and is characterized in that: the hydraulic engineering bears the tasks of water blocking, water storage and water drainage, so that special requirements on the stability, pressure bearing, seepage prevention, impact resistance, wear resistance, freezing resistance, crack resistance and other performances of the hydraulic building are met, and special construction methods and measures are adopted according to the technical specifications of the hydraulic engineering to ensure the engineering quality; the hydraulic engineering has strict requirements on the foundation, the engineering is often positioned in areas and parts with complex geological conditions, hidden danger is left when the foundation is not well treated, the foundation is difficult to remedy after that, and special foundation treatment measures are needed; the hydraulic engineering is mainly constructed in river channels, lakes, coasts and other water areas, and needs to perform construction diversion, interception and underwater operation according to the natural conditions of water flow and the requirements of engineering construction; the hydraulic engineering is constructed in a dead water period by fully utilizing the dead water, has strong seasonality and necessary construction strength, and also needs to take temperature control measures due to the influence of climate so as to ensure the engineering quality. The hydraulic engineering construction has close relation with society and natural environment, so the influence of implementing engineering is larger, the opportunity is needed to be mastered, the plan is reasonably arranged, the construction is carefully organized, and the problems of flood control, flood control and the like in the construction are solved in time so as to ensure safety.

At present, along with the development of scientific technology, the fields of construction and the like are rapidly developed, a large amount of concrete is required in daily construction, and in order to improve the construction speed, some block-shaped concrete blocks on the road side and the flower garden side are all cast into concrete blocks in factories and then transported to the site for enclosing to form flower garden curbstones.

The concrete pouring refers to the process of pouring concrete into a mould until plasticization, materials such as concrete and the like are placed into the mould to form a preset shape in civil construction engineering, the free height of the concrete is not more than 2m when the concrete is poured, and corresponding measures are taken when the free height of the concrete exceeds 3 m.

The concrete blocks are mainly prepared by mixing cement, sand aggregate and water by a casting machine and stirring the mixture into concrete mixture, and then pouring the concrete mixture into a corresponding model for solidification to form the road edge stone.

The existing concrete pouring equipment can continuously stir concrete before pouring so as to ensure that the internal stone slag can be uniformly mixed in the concrete, and the problems of uneven pouring of finished products and poor mixing quality caused by accumulation of more stone slag at the same position are avoided.

Disclosure of Invention

The embodiment of the invention aims to provide concrete pouring equipment for hydraulic engineering construction, and aims to solve the problems that the existing concrete pouring equipment can continuously stir concrete before pouring so as to ensure that internal stone residues can be uniformly mixed in the concrete, and more stone residues are prevented from being accumulated at the same position, so that the pouring of finished products is uneven and the mixing quality is poor.

The embodiment of the invention is realized in such a way that the concrete pouring equipment for hydraulic engineering construction comprises:

the concrete pretreatment device comprises support frames, wherein a tank body is arranged between the support frames, and a stirring mechanism is arranged in the tank body and used for pretreating concrete;

the feeding pipe is arranged on the supporting frame, and a pouring pipe is arranged at one side of the tank body;

and the control mechanism is arranged on the supporting frame, is connected with the stirring mechanism and is used for adjusting the operation mode of the stirring mechanism.

Preferably, the stirring mechanism comprises:

the installation groove is formed in the inner wall of the tank body, a guide column is arranged in the installation groove, and a sliding block is sleeved on the guide column in a sliding manner;

the telescopic link is installed on the sliding block, driving motor is installed to telescopic link one end, driving motor's output is connected with the pivot, the stirring piece is installed to the pivot lateral part.

Preferably, the number of the mounting grooves, the guide posts, the sliding blocks and the telescopic rods is not less than two, and the mounting grooves, the guide posts, the sliding blocks and the telescopic rods are symmetrically arranged on the inner wall of the tank body.

Preferably, the control mechanism includes:

the support plate is arranged on the support frame and is provided with a bidirectional motor;

the lifting displacement mechanism and the transverse displacement mechanism are respectively arranged at two sides of the supporting plate and are connected with the bidirectional motor;

the connecting column is arranged on the stirring mechanism, a first linkage groove is arranged at one end of the connecting column, and a linkage block is sleeved on the connecting column in a sliding manner.

Preferably, the elevating displacement mechanism comprises:

the first turntable is arranged at the output end of the bidirectional motor, and plate grooves are symmetrically formed in the first turntable;

the first rotary rod is rotationally connected to one side of the supporting plate, a first guide column is arranged on the first rotary rod, the first guide column is matched with the first rotary table and the plate groove, a first linkage column is arranged at one end of the first rotary rod, and the first linkage column is matched with the first linkage groove;

and one end of the first spring is connected with the middle part of the first rotating rod.

Preferably, the lateral displacement mechanism comprises:

the second turntable is arranged at the output end of the bidirectional motor, and a guide lug is arranged on the second turntable;

the second rotating rod is rotatably connected to one side of the supporting plate, a second guide post is arranged on the second rotating rod, the second guide post is matched with the second turntable and the guide convex block, and a second linkage post is arranged at one end of the second rotating rod;

the second spring is arranged on the supporting plate, and one end of the second spring is connected with the middle part of the second rotating rod;

the control groove is arranged on one side of the supporting plate, a sliding rod is arranged in the control groove in a sliding mode, a connecting rod is arranged on the sliding rod, one end of the connecting rod is connected with the linkage block, a second linkage groove is arranged on the connecting rod, and the second linkage column is matched with the second linkage groove.

Preferably, the first spring and the second spring are always in a stretched state.

The concrete pouring equipment for hydraulic engineering construction provided by the embodiment of the invention has the following beneficial effects:

when this concrete placement equipment for hydraulic engineering construction uses, add the concrete raw materials to jar internal portion through the inlet pipe, then start rabbling mechanism, then rabbling mechanism can stir the concrete raw materials, start control mechanism simultaneously, control mechanism can drive rabbling mechanism and carry out sustainable position adjustment, constantly change rabbling mechanism's working position, make jar internal portion hungry concrete's stirring more abundant, avoid the edge to have the stone residue to remain, promote the treatment effect of concrete, and the concrete accessible after handling pours the pipe discharge, and pour the operation.

Drawings

Fig. 1 is a schematic structural diagram of a concrete pouring device for hydraulic engineering construction according to an embodiment of the present invention;

fig. 2 is a schematic structural view 1 of a control mechanism in concrete pouring equipment for hydraulic engineering construction according to an embodiment of the present invention;

fig. 3 is a schematic structural view 2 of a control mechanism in a concrete pouring device for hydraulic engineering construction according to an embodiment of the present invention;

fig. 4 is a schematic structural view 3 of a control mechanism in a concrete pouring device for hydraulic engineering construction according to an embodiment of the present invention;

fig. 5 is a schematic structural view 4 of a control mechanism in a concrete pouring device for hydraulic engineering construction according to an embodiment of the present invention;

fig. 6 is a partial enlarged view at a in fig. 1.

In the accompanying drawings: 1-a supporting frame; 2-a tank body; 3-a stirring mechanism; 31-mounting grooves; 32-guide posts; 33-sliding blocks; 34-a telescopic rod; 35-driving a motor; 36-rotating shaft; 37-stirring sheet; 4-feeding pipe; 5-pouring a pipe; 6-a control mechanism; 61-supporting the plate; 62-a bi-directional motor; 63-connecting columns; 64-a first linkage groove; 65-linkage blocks; 66-a first turntable; 67-plate grooves; 68-a first rotary rod; 69-a first guide post; 610-a first linkage column; 611-a first spring; 612-a second carousel; 613-guide lugs; 614-a second rotary lever; 615-a second guide post; 616-a second linkage column; 617-a second spring; 618-a control slot; 619-slide bar; 620-connecting rod; 621-a second linkage groove.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Specific implementations of the invention are described in detail below in connection with specific embodiments.

As shown in fig. 1, in an embodiment of the present invention, the concrete placement equipment for hydraulic engineering construction includes:

the concrete pretreatment device comprises a support frame 1, wherein a tank body 2 is arranged between the support frames 1, a stirring mechanism 3 is arranged in the tank body 2, and the stirring mechanism 3 is used for pretreating concrete;

the feeding pipe 4 is arranged on the support frame 1, and a pouring pipe 5 is arranged on one side of the tank body 2;

and the control mechanism 6 is arranged on the support frame 1, and the control mechanism 6 is connected with the stirring mechanism 3 and is used for adjusting the operation mode of the stirring mechanism 3.

When this concrete placement equipment for hydraulic engineering construction uses, add the concrete raw materials to jar body 2 inside through inlet pipe 4, then start rabbling mechanism 3, then rabbling mechanism 3 can stir the concrete raw materials, start control mechanism 6 simultaneously, control mechanism 6 can drive rabbling mechanism 3 and carry out sustainable position adjustment, constantly change the working position of rabbling mechanism 3, make jar body 2 inside hungry concrete's stirring more abundant, avoid the edge position to have stone residue to remain, promote the treatment effect of concrete, and the concrete accessible after the processing pours 5 discharges of pipe, and pour the operation.

As shown in fig. 1 and 2, in the embodiment of the present invention, the stirring mechanism 3 includes:

the installation groove 31 is formed in the inner wall of the tank body 2, a guide column 32 is arranged in the installation groove 31, and a sliding block 33 is sleeved on the guide column 32 in a sliding manner;

the telescopic link 34 is installed on the sliding block 33, driving motor 35 is installed to telescopic link 34 one end, driving motor 35's output is connected with pivot 36, stirring piece 37 is installed to pivot 36 lateral part.

When the stirring device is used, the driving motor 35 is started, the driving motor 35 drives the stirring sheet 37 to rotate through the rotating shaft 36, so that stirring operation is realized, and the structures of the sliding block 33 and the telescopic rod 34 can adapt to the operation of the control mechanism 6, so that the stirring mechanism 3 can lift and transversely move, and the stirring effect is enriched.

In the embodiment of the present invention, the number of the installation grooves 31, the guide posts 32, the sliding blocks 33 and the telescopic rods 34 is not less than two, and the installation grooves are symmetrically installed on the inner wall of the tank body 2.

As shown in fig. 1 to 6, in the embodiment of the present invention, the control mechanism 6 includes:

a support plate 61 mounted on the support frame 1, the support plate 61 being mounted with a bi-directional motor 62;

the lifting displacement mechanism and the transverse displacement mechanism are respectively arranged at two sides of the supporting plate 61 and are connected with the bidirectional motor 62;

the connecting column 63 is installed on the stirring mechanism 3, a first linkage groove 64 is installed at one end of the connecting column 63, and a linkage block 65 is sleeved on the connecting column 63 in a sliding manner.

As shown in fig. 1 to 6, in the embodiment of the present invention, the elevating displacement mechanism includes:

the first turntable 66 is mounted on the output end of the bidirectional motor 62, and the first turntable 66 is symmetrically provided with plate grooves 67;

the first rotating rod 68 is rotatably connected to one side of the supporting plate 61, a first guide post 69 is mounted on the first rotating rod 68, the first guide post 69 is matched with the first rotating plate 66 and the plate groove 67, a first linkage post 610 is mounted at one end of the first rotating rod 68, and the first linkage post 610 is matched with the first linkage groove 64;

a first spring 611 installed at one side of the support plate 61, and one end of the first spring 611 is connected to the middle of the first rotating rod 68.

When in use, the bi-directional motor 62 is started, the bi-directional motor 62 drives the first rotating disc 66 to rotate, and controls the first guide post 69 through the distance difference between the edge of the first rotating disc 66 and the center of the plate groove 67 from the first rotating disc 66, so as to drive the first rotating rod 68 to perform the reciprocating swinging effect, and then the first rotating rod 68 drives the connecting post 63 to perform lifting operation through the matching relationship between the first linkage post 610 and the first linkage groove 64, so as to drive the stirring mechanism 3 to perform lifting operation.

As shown in fig. 1 to 6, in the embodiment of the present invention, the lateral displacement mechanism includes:

the second turntable 612 is mounted at the output end of the bidirectional motor 62, and a guide lug 613 is mounted on the second turntable 612;

the second rotating rod 614 is rotatably connected to one side of the supporting plate 61, a second guide post 615 is mounted on the second rotating rod 614, the second guide post 615 is matched with the second turntable 612 and the guide projection 613, and a second linkage post 616 is mounted at one end of the second rotating rod 614;

a second spring 617 mounted on the support plate 61, one end of the second spring 617 being connected to a middle portion of the second rotating lever 614;

the control groove 618 is installed in one side of the supporting plate 61, a sliding rod 619 is slidably arranged in the control groove 618, a connecting rod 620 is installed on the sliding rod 619, one end of the connecting rod 620 is connected with the linkage block 65, a second linkage groove 621 is installed on the connecting rod 620, and the second linkage post 616 is matched with the second linkage groove 621.

When in use, the operation of the bidirectional motor 62 drives the second rotary table 612 to rotate, and controls the second guide column 615 through the distance difference between the edge of the second rotary table 612 and the center of the guide projection 613 from the second rotary table 612, so as to drive the second rotary rod 614 to swing, and then the swing of the second rotary rod 614 drives the slide rod 619 to perform the effect of the transverse reciprocating movement through the cooperation between the second linkage column 616 and the second linkage groove 621, so as to pull the connecting column 63 to move, and make the stirring mechanism 3 perform the synchronous transverse movement.

In the embodiment of the present invention, the first spring 611 and the second spring 617 are always in a stretched state.

To sum up, when this concrete placement equipment for hydraulic engineering construction uses, add the concrete raw materials to the jar body 2 inside through inlet pipe 4, then start rabbling mechanism 3, then rabbling mechanism 3 can stir the concrete raw materials, start control mechanism 6 simultaneously, control mechanism 6 can drive rabbling mechanism 3 and carry out the position adjustment of persistence, constantly change the working position of rabbling mechanism 3, make the stirring of the inside hungry concrete of jar body 2 more abundant, avoid the edge to have the stone sediment to remain, promote the treatment effect of concrete, and the concrete accessible after the processing pours 5 discharges of pipe, and pour the operation.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (4)

1. The utility model provides a concrete placement equipment for hydraulic engineering construction, its characterized in that, concrete placement equipment for hydraulic engineering construction includes:

the concrete pretreatment device comprises support frames, wherein a tank body is arranged between the support frames, and a stirring mechanism is arranged in the tank body and used for pretreating concrete;

the feeding pipe is arranged on the supporting frame, and a pouring pipe is arranged at one side of the tank body;

the control mechanism is arranged on the supporting frame, is connected with the stirring mechanism and is used for adjusting the operation mode of the stirring mechanism;

wherein the control mechanism comprises:

the support plate is arranged on the support frame and is provided with a bidirectional motor;

the lifting displacement mechanism and the transverse displacement mechanism are respectively arranged at two sides of the supporting plate and are connected with the bidirectional motor;

the connecting column is arranged on the stirring mechanism, a first linkage groove is arranged at one end of the connecting column, and a linkage block is sleeved on the connecting column in a sliding manner;

the lifting displacement mechanism comprises:

the first turntable is arranged at the output end of the bidirectional motor, and plate grooves are symmetrically formed in the first turntable;

the first rotary rod is rotationally connected to one side of the supporting plate, a first guide column is arranged on the first rotary rod, the first guide column is matched with the first rotary table and the plate groove, a first linkage column is arranged at one end of the first rotary rod, and the first linkage column is matched with the first linkage groove;

the first spring is arranged on one side of the supporting plate, and one end of the first spring is connected with the middle part of the first rotating rod;

the lateral displacement mechanism includes:

the second turntable is arranged at the output end of the bidirectional motor, and a guide lug is arranged on the second turntable;

the second rotating rod is rotatably connected to one side of the supporting plate, a second guide post is arranged on the second rotating rod, the second guide post is matched with the second turntable and the guide convex block, and a second linkage post is arranged at one end of the second rotating rod;

the second spring is arranged on the supporting plate, and one end of the second spring is connected with the middle part of the second rotating rod;

the control groove is arranged on one side of the supporting plate, a sliding rod is arranged in the control groove in a sliding mode, a connecting rod is arranged on the sliding rod, one end of the connecting rod is connected with the linkage block, a second linkage groove is arranged on the connecting rod, and the second linkage column is matched with the second linkage groove.

2. The concrete placement equipment for hydraulic engineering construction according to claim 1, wherein the stirring mechanism includes:

the installation groove is formed in the inner wall of the tank body, a guide column is arranged in the installation groove, and a sliding block is sleeved on the guide column in a sliding manner;

the telescopic link is installed on the sliding block, driving motor is installed to telescopic link one end, driving motor's output is connected with the pivot, the stirring piece is installed to the pivot lateral part.

3. The concrete placement equipment for hydraulic engineering construction according to claim 2, wherein the number of the installation grooves, the guide posts, the sliding blocks and the telescopic rods is not less than two, and the installation grooves, the guide posts, the sliding blocks and the telescopic rods are symmetrically installed on the inner wall of the tank body.

4. The concrete placement equipment for hydraulic engineering construction according to claim 1, wherein the first spring and the second spring are always in a stretched state.